Increasing the growth rate of teak trees is carried out to shorten the tree harvest rotation and reduce the deficit of teak timber supply, while maintaining the superiority of wood properties. The study was conducted to study the nature of five-year-old JUN Teak wood in three classes of tree diameter and radial position of the trunk. This study employed a completely randomized design arranged in factorial combinations of the treatments of radial positions and diameter classes consisting of large (18-22 cm), medium (14-18 cm) and small (10-14 cm) stem diameters, and the radial position of wood on the trunk based on the tree's ring. Three samples of trees were felled for each stem diameter class so that totally nine trees were used in this study. The testing of the physical properties of wood and the measurement of fiber dimensions were conducted using British Standards 373 and the IAWA method, respectively. The results showed that the diameter of the tree and the radial position of the wood had a significant effect on all parameters observed (fiber dimension and physical properties of wood), except the fiber diameter. The tree growth rate had a negative correlation with fiber length (-0.67), fiber wall thickness (-0.65), air-dry moisture content (-0.91) and air dry specific gravity (-0.86), and had a positive correlation with fiber diameter (0.61) and green water content (0.78). According to the pattern of wood properties in the radial direction, JUN wood harvested at the age of five was categorized as juvenile wood. This wood is acceptable as furniture and lightweight construction material.

Anoop EV, Anish MC, Vishnu R. dkk. (2015). Effect of growth rate on wood quality of teak (Tectona grandis L. f.): A comparative study of teak grown under differing site quality conditions. J. Indian Acad. Wood Sci. 12: 81–88.

Basri E & Wahyudi I. 2013. Wood basic properties of teak plus perhutani from different ages and their relationships to drying properties and qualities. Forest Products Research Journal Vol. 31 (2): 93-102.

Bhat K, Priya P, Rugmini, P. 2001. Characterization of juvenile wood in teak. Wood Sci. Technol. 34: 517-532.

British Standard, 1957. Methods of testing small clear specimens of timber. British Standards Institution. London

Cardoso S, Sousa VB, Quilhó T, Pereira H. 2015. Anatomical variation of teakwood from unmanaged mature plantations in East Timor. J. Wood Sci. 61 (3): 326-333

Efhamisisi D, Karimi AN, Pourtahmasi K & Asadi F. 2016. The relationships between fiber dimensions and growth rate in Populus nigra. J. Wood For. Sci. Technol. 23(2): 169-183.

Fo M & Roque R. 2007. Wood density and fiber dimensions of "Gmelina arborea" in fast growth trees in Costa Rica: relation to the growth rate. Investigacion agraria. Sist. Recur. For. 16(3): 267-276.

Fujiwara S, Takamura N, Sameshima K, Kuroda K. 1991. Anatomy and properties of japanese hardwoods I. variation of fibre dimensions and tissue proportions and their relation to basic density. IAWA J. 12: 419-424.

Glass SV & Zelinka SL. 2010. Moisture relations and physical properties of wood in wood handbook: Wood as an engineering material. United States Department of Agriculture - Forest Service - Forest Products Laboratory, Madison, Wisconsin

Gryc V., Vavrcik H., and Horn K., 2011. Density of juvenile and mature wood of selected coniferous species. J. For. Sci 57: 123–130

Haroen WK. 2017. Hubungan specific gravity kayu daun terhadap serat dan kualitas pulp. J. Seluosa. 5(2): 59-68

Herritsch. 2007. Investigations on wood stability and related properties of radiata pine. disertasi. Tidak dipublikasikan. University of Canterbury. New Zealand

Hidayati F, Ishiguri F, Iizuka K, dkk. 2014. Among-clone variations of anatomical characteristics and wood properties in Tectona grandis planted in Indonesia. Wood Fiber Sci. 46:385-393.

IAWA, 2008. IAWA list of microscope features for hardwood identification. Center for Forest Product Research and Development. Bogor

Jayawardana D & Amarasekera H. 2009. Effect of growth rate on wood quality of teak (Tectona grandis Lf) plantations at Malsiripura, Kurunegala, Sri Lanka. Vidyodaya J. Gold. Jub. Issue: 149-170

Jha KK. 2016. What should be the rotation age and harvest management in Teak. Indian For. J. 142 (4): 309-316.

Karlinasari, L., Andini, S., Worabai, D. dkk 2018. Tree growth performance and estimation of wood quality in plantation trials for Maesopsis eminii and Shorea spp.. J. For. Res. 29: 1157–1166.

Kiaei M, Naji HR, Abdul-Hamid H, Farsi M. 2016. Radial variation of fiber dimensions, annual ring width, and wood density from natural and plantation trees of alder (Alnus glutinosa) wood. Wood Res. J. 61 (1): 55-64

Kojima M, Yamamoto H, Ojio KOY, dkk, 2009. Effect of the lateral growth rate on wood properties in fast-growing hardwood species. Wood Sci. J. 55: 417-424

Kojima, M., H. Yamamoto, SN Marsoem, dkk. 2009. Effects of the lateral growth rate on wood quality of Gmelina arborea from 3.5-, 7- and 12-year-old plantations. Ann. For. Sci. 66 (507): 502-507.

Lachenbruch B, Moore JR, Evans R. 2011. Radial variations in wood structures and functions in woody plants, and hypotheses for its occurrence. In: Meinzer FC, Lachenbruch B & Dawson TE (eds.), Size and age-related changes in tree structure and function. Tree Physiol. 4: 121–164.

Lacret R, Varela RM, Molinillo JMG, Nogueiras C, Macias FA. 2012. Tectonoelins, ew or lignans from a bioactive extract of Tectona grandis. Phytochem. Lett. 5: 382−386..

Lukmandaru G, 2011. Variability in the natural termite resistance of plantation teak wood and its relationship with wood extractive content and color properties. J. For. Res. 8 (1): 1817-31

Malik MFEI & Abdelgadir AY. 2015. Effect of growth rate on wood density of Eucalyptus camaldulensis wood of coppice origin grown in White Nile State Sudan. J. For. Prod. Ind. 4(3):86-93

Marsoem, SN, D. Puspitasari, A. Pramudita, Y. Ermaningsih, 2008. Analysis of the quality of the Perhutani JPP timber test for 10-year age descent. Perhutani Public Corporation Research and Development Center, Cepu.

Marsoem, SN, FE Prasetyo, J. Sulistyo, dkk. 2014. Gunungkidul community forest teak quality study: III. Nature of wood. J. For. Sci. 8 (2): 75-88

Missanjo E. & Matsumura J., 2016. Radial variation in tracheid length and growth ring Width of Pine kesiya Royle ex Gordon in Malawi. Int. J. Res. Agric. For. 3 (1): 13-21

Mohamad S & Marsoem SN. 2007. Characteristics and variations in physical properties of Acacia mangium Wild wood at some distance and axial-radial position. J. Pemuliaan Tanam. Hutan 1(1):1-13

Mugasha WA, Bollandsås OM & Eid T. 2013. Relationships between diameter and height of trees in natural tropical forest in Tanzania. Southern Forests: J. F. Sci. 75(4): 221-237.

Naji HR, Sahri MH, Nobuchi1 T & Bakar ES. 2012. The effect of growth rate on wood density and anatomical characteristics of rubberwood (Hevea brasiliensis Muell. Arg.) in two different clonal trails. J. Nat. Prod. Plant Resources, 1 (2): 71-80

Nugroho DN, Marsoem SN, Yasue K, dkk. 2011. Radial variations in the anatomical characteristics and density of the wood of Acacia mangium of five different provenances in Indonesia. J. Wood Sci. 58:185–194

Panshin, AJ. dan de Zeeuw C, 1980. Text Book of Wood Technology. Structure Identification. Properties and Use of The Comercial Wood of The United States and Canada. Me. Graw-Hill Book Company. New York.

Perhutani, 2019a. Statistik Perum Perhutani Tahun 2014-2018. Perum Perhutani, Jakarta

Perhutani, 2019b. Perhutani memacu tanaman biomassa. https://perhutani.co.id

Pertiwi YAB, Aiso H, Ishiguri F, dkk. 2017. Effect of radial growth rate on wood properties of Neolamarckia cadamba. Journal of Tropical Forest Science Vol. 29, No. 1 pp. 30-36

Rizanti DE, Darmawan W, George B, dkk. 2018. Comparison of teak wood properties according to forest management: short versus long rotation. Ann. For. Sci. 75(39).

Shmulsky R. and Jones PD, 2019. Forest products and wood science. An Introduction. A John Wiley & Sons, Inc., UK.

Shukla SR & Viswanath S. 2014. Comparative study on growth, wood quality and financial returns of teak (Tectona grandis L.f.) managed under three different agroforestry practices. Agroforest Syst 88(2):331-341.

Sousa VB, Cardoso S, Quilho T & Pereira H. 2012. Growth rate and ring width variability of teak, Tectona grandis (Verbenaceae) in an unmanaged forest in East Timor. Rev. Biol. Trop. 60(1): 83-94

Sugiyono. 2013. Metode penelitian kuantitatif, kualitatif dan R&D. Bandung: Alfabeta.CV

Sumida A, Miyaura T, Torii H. 2013. Relationships of tree height and diameter at breast height revisited: analyses of stem growth using 20-year data of an even-aged Chamaecyparis obtusa stand. Tree Physiol. 33: 106–118

Wahyudi I & Arifien AF. 2005. Perbandingan struktur anatomis, sifat fisis dan sifat mekanis kayu jati unggul dan kayu jati konvensional. J. Ilmu Teknol. Kayu Trop. 3 (2): 53-59.

Wahyudi I, PriadiT, Rahayu IS . 2014. Karakteristik dan sifat-sifat dasar kayu jati unggul umur 4 dan 5 tahun asal Jawa Barat. J. Ilmu Pertan. Indones. 19(1): 50-56.

Yudhanto & Sulistyo. 2013. Dimensi serat dan sifat fisika kayu Shorea macroptera dan Shorea retusa yang tumbuh di Kalimantan Timur. http://etd.repository.ugm.ac.id/ penelitian/detail/65274

Zahabu E, Raphael T, Chamshama SAO, Iddi S & Malimbwi RE. 2015. Effect of spacing regimes on growth, yield, and wood properties of Tectona grandis at Longuza forest plantation, Tanzania. Int. J. For. Res.. 26(3):1-16

Zieminska K, Butler D, Gleason SM, Wright IJ, dan Mark W. 2013. Fibre wall and lumen fractions drive wood density variation across 24 Australian angiosperms. Ann. Bot. 5:1-14.